Disk brake comprising a cooling member

ABSTRACT

The invention relates to a disk brake, especially for a motor vehicle, comprising a rotatably mounted brake disk and at least one brake lining that is disposed in a caliper and is mounted so as to be laterally movable towards the brake disk. In order to reduce heating of the brake disk during braking, a cooling member is provided which is made of a heat-conducting material and encompasses at least one fastening element. The fastening element allows the cooling member to be arranged in a position in which the heat-receiving face thereof is located on one side of the brake disk while the area of the cooling member, which is located away from the heat-receiving face, is connected to a cooler.

The invention relates to a disk brake of the type specified in the preamble of claim 1.

In a braking process the friction which occurs between the brake disk and the brake linings produces heat which is transferred to the components involved and especially to the brake disk. To protect the materials and components involved, there is a requirement for a temperature as low as possible in the area of the components involved. For strong and longer braking the temperature can however reach a level which is damaging to the affected components.

The object of the invention is to find a configuration for a brake disk of the current type in which heating is reduced while avoiding the indicated disadvantages.

This object is achieved by the characterizing features specified in claim 1 in conjunction with the features of its preamble.

The dependent claims form advantageous developments of the invention.

The invention is based on the finding that heating can be reduced by concerted dissipation of heat from the brake disk.

As claimed in the invention, the disk brake has a cooling member of heat conductive material which is provided at least with one fastening component with which it can be configured in the position in which its heat absorption side is located on one side of the brake disk, and with its area located away from the heat absorption side is connected to a cooler. The cooling member removes heat in a concerted manner from the brake disk, transfers it to the cooling member and the heat is dissipated by the cooler. As a result, potential heating of the brake disk, which might otherwise occur, is greatly reduced. Moreover, the heating of the brake linings and their adjacent components is reduced since the brake disk absorbs heat from these components as a result of its reduced possible heating.

Preferably the heat-conducting material of the cooling member consists of copper or highly heat-conducting plastic, the copper or the heat-conducting plastic having preferably embedded, highly heat-conducting carbon fibers. In particular the carbon fibers run transversely to the heat absorption side. In this way, on the one hand high heat conduction in the cooling member and thus also efficient transport of the heat to the cooler are guaranteed. Highly heat-conductive carbon fibers which are commercially available with a specific thermal conductivity of up to 1000 W/(mK) facilitate this high heat conduction. Even where these carbon fibers are processed by embedding into available components which are known on the specialty market under the description “CPK components” thermal conductivity up to 600 W/(mK) can be achieved. On the other hand, these materials are lighter than aluminum. The cooling member for disk brakes leads to weigh reduction since the double-walled vented brake disk is replaced by a light disk ring without cooling air guides.

Heat absorption can be improved primarily when the carbon fibers are jacketed, especially sprayed, with a metal, especially copper; this contributes to efficient heat conduction in the cooling member.

According to one embodiment of the invention, the carbon fibers stand up on the heat absorption side and/or on the rear side which is located away from the heat absorption side like fur hairs. On the one hand this improves heat transfer to the carbon fibers and on the other from the latter to the cooling medium. The ends of the carbon fibers can be coated with artificial diamond using nanotechnology, by which the heat transfer is improved, a lower coefficient of friction is preserved and wear resistance is greatly increased.

Moreover, the stability of the cooling member can be increased and the possibilities of its attachment in the area of the disk brake can be improved if the material of the cooling member is enclosed by a frame.

Preferably on the rear side of the cooling member located away from the heat absorbing side there is a cavity which is enclosed by a housing and which is connected to the cooling circuit. This facilitates efficient dissipation of heat from the rear side of the cooling member.

According to one embodiment of the invention, the fastening element is configured more or less in the middle in the rear side which is located away from the heat absorption side. In this way simple support for the cooling member is made possible, for support on only one support point an optimum position of the heat absorption side relative to the brake disk being ensured.

Preferably the fastening element is connected to a spring, especially a leaf spring, with a spring path which is aligned transversely to the heat absorption side and holds the cooling member on the side of the brake disk. The contact of the heat absorption side with the brake disk for an air gap equal to zero is ensured in this way and therefore also optimum heat transmission. Moreover automatic tracking of the cooling member as the brake disk wears is ensured so that the air gap always remains equal to zero.

Other advantages, features and possible applications of this invention follow from the description below in conjunction with the embodiment shown in the drawings.

The invention is detailed below using the embodiment shown in the drawings. In the specification, in the claims, in the abstract, and in the drawings the terms and assigned reference numbers used in the list of reference numbers given in the back are used.

FIG. 1 shows a simplified side view of the upper half of a disk brake of a motor vehicle, especially a passenger car, with a cooling member as claimed in the invention;

FIG. 2 shows an overhead view of the disk brake; and

FIG. 3 shows a simplified partial section along line III-III in FIG. 1.

The disk brake designated as 10 in its entirety has a brake disk 12 in the form of a flat disk ring which is attached to an annular brake disk carrier 14 which is attached to a body of revolution 16 in a manner which is not shown, for example a rotatably mounted and optionally driven and optionally steerable wheel shaft or wheel axle. Of the body of revolution 16 or the wheel shaft or wheel axle, only the axis of rotation 18 is shown in FIG. 3.

On both sides of the brake disk 12 there is one, for example, disk-shaped, brake lining 20 each in one caliper 22. By actuating the brake pedal (not shown) in the conventional manner the brake disk 12 can be squeezed between the brake linings 20, by which the braking process is initiated. The caliper 22 which encloses the brake disk 12 for example in a U-shape is fixed relative to the axis of rotation 18 in a manner which is not shown. It can be attached to a wheel bearing carrier which is not shown.

The brake disk 12 can be configured differently and can consist for example of metal, especially gray cast iron or preferably alloyed steel. But it can also consist of ceramic or can be coated with ceramic in the area of its friction surfaces. Sintered aluminum ceramic fibers and carbon fibers (silicon carbide) are suitable as ceramic material. The ceramic coating can be arranged in the form of a ring, or segmented, for example in the form of segments which are fixed on a carrier ring. The brake disk 12 is preferably designed single-walled, by which a small construction mode is achieved and material and weight are saved.

In braking operation, due to friction, heat which the brake disk 12 absorbs as solid-borne heat is generated and it can be of such a high temperature that the brake disk 12 itself or even adjacent parts of the disk brakes 10 or the body of the vehicle can suffer damage.

Offset in the peripheral direction to the brake lining 20 which is configured on one side or both sides, on one side or one both sides of the brake disk 12 there is one cooling member 24 each which absorbs part of this heat and dissipates it and in this way reduces the temperature transferred to the brake disk 12 in the braking process or does not allow it to rise so greatly.

The cooling member 24 is part of a cooling means 26 and has a plate shape with a flat heat absorption surface 28 on its side facing the brake disk 12. The cooling member 24 consists of a material of high thermal conductivity, especially of embedded carbon fibers 24 a, preferably highly heat conductive carbon fibers 24 a which are known in a form processed into components as CFK components. The carbon fibers 24 a are joined with a matrix into a solid material.

In one preferred configuration the carbon fibers 24 a are configured in an alignment transverse to the heat absorption side 28 and are connected to one another on their jacket surfaces. In the process the carbon fibers 24 a can be jacketed, preferably extrusion-coated, with metal, especially metal of high thermal conductivity, such as copper, for example. On the one hand, in this way thermal conductivity and on the other hand mechanical coherence are improved. The fiber material and the fibers can be enclosed by a frame 30, by which the strength and stability of the cooling member 24 are further increased.

The cooling member 24 interacts on its rear side facing away from the heat absorbing side 28 with a cooler 32 and is connected to it. In this way the heat routed to the rear side in the cooling member 24 is dissipated. The cooler 32 can function with a vaporizing medium for the purpose of a so-called heat pipe.

In the embodiment there is a cooling circuit 34 with a preferably liquid cooling medium, for example water. The cooling circuit 34 flows through a sealed cavity 36 which is configured on the rear side and which is bordered on the rear side and on its periphery by a housing 38. The housing can be a one-piece section or a rear-side add-on piece of the frame 30. A supply line and discharge line which pass through the housing 38 are designated as 34 a and 34 b.

It is preferable if the carbon fibers 24 a on the heat absorption side 28 and/or the rear side rise above the embedding in the cooling member 24 and stick out like short fur hairs, and thus project into the cooling medium on the rear side. The metal enclosing the carbon fibers 24 a improves the heat conduction. Carbon fibers in addition to their high thermal conductivity also have the advantage of being able to capture and relay radiant heat with high efficiency due to their black color.

The cooling member 24 can be attached directly or by its frame 30 or the housing 38 relative to the axis of rotation 18, for example to the caliper 22. One especially advantageous position for the cooling member 24 is in the direction of rotation 40 of the brake disk 12 directly behind the brake linings 20 or the caliper 22 where the temperature is the highest.

The air gap between the heat absorbing side 28 and the brake disk 12 should be as small as possible for purposes of good heat transmission. The cooling member 24 can also lightly adjoin the brake disk 12. As FIG. 2 shows, the carbon fibers 24 a sticking out on the heat absorption side 28 can be elastically flexible and adjoin the brake disk 12 somewhat bent. In this way an air gap which is formed by wear on the brake disk 12 can be automatically bridged by relief motion of the carbon fibers 24 a so that an air gap is avoided.

An air gap can also be avoided when the cooling member 24 is movably guided in a guide 42 which is directed transversely to the heat absorption side 28 and is lightly pretensioned by the force of a spring 42 against the brake disk 12. In the embodiment the cooling member 24 is held, guided, and pretensioned lightly against the brake disk 12 by the spring 44. The spring 44 is preferably a leaf spring which is attached preferably in the middle area of the rear wall of the housing 38 on a fastening element 46 which is configured on the rear wall. In its other end area the spring 44 is attached for example to the caliper 22 or to an add-on piece of the latter. The fastening elements can be for example holes for screws or rivets which are suggested by the center lines.

The cooling bodies 24 or cooling means 26 which are configured on both sides of the brake disk 12 are arranged mirror-symmetrically relative to the brake disk 12. The discharge line 34 b of one cooling member 24 and the supply line 34 a of the other cooling member 24 can be formed by a common connecting line 34 c which bypasses the brake disk 12.

When the cooling bodies 24 are configured to be movable against the brake disk 12, the supply lines and discharge lines 34 a, 34 b, 34 c are flexible lines.

REFERENCE NUMBER LIST

-   10 disk brake -   12 brake disk -   14 brake disk carrier -   16 body of revolution -   18 axis of rotation -   20 brake lining -   22 caliper -   24 cooling member -   24 a carbon fibers -   26 cooling means -   28 heat absorbing side -   30 frame -   32 cooler -   34 cooling circuit -   34 a supply line -   34 b discharge line -   34 c connecting line -   36 cavity -   38 housing -   40 direction of rotation -   44 spring -   46 fastener 

1. Disk brake, comprising a rotatably mounted brake disk and at least one brake lining which is configured in a caliper and which is mounted so as to be laterally movable against the brake disk, a cooling member of a heat-conducting material which has at least one fastening element wherein a heat absorption side of thereof is configured on one side of the brake disk and which is connected to a cooler, wherein the heat-conducting material of the cooling member comprises embedded, highly heat-conducting carbon fibers positioned transversely to the heat absorption side, and that the cooling member on its rear side facing away from the heat absorption side is connected to the cooler interacting therein.
 2. The disk brake as claimed in claim 1, wherein the carbon fibers are jacketed, especially extrusion-coated, with a metal, preferably copper.
 3. The disk brake as claimed in claim 1, wherein the carbon fibers on the heat absorption side and/or on the rear side located away from the heat absorption side stick up, coated using nanotechnology with artificial diamond.
 4. The disk brake as claimed in claim 1, wherein the heat-conducting material of the cooling member is enclosed by a frame.
 5. The disk brake as claimed in claim 1, wherein on the rear side of the cooling member which is located away from the heat absorption side there is a cavity which is enclosed by a housing and which is connected to a cooling circuit.
 6. The disk brake as claimed in claim 1, wherein the fastening element is positioned more or less in the middle on the rear side which is located away from the heat absorption side.
 7. The disk brake as claimed in claim 1, wherein the fastening element is connected to a spring, with a spring path which is directed transversely to the heat absorption side and which holds the cooling member on the side of the brake disk.
 8. The disk brake as claimed in claim 1, wherein on the rear side of the cooling member which is located away from the heat absorption side there is a cavity which is enclosed by a housing and which is connected to a cooling circuit.
 9. The disk brake as claimed in claim 1, wherein the fastening element is positioned more or less in the middle on the rear side which is located away from the heat absorption side.
 10. The disk brake as claimed in claim 1, wherein the fastening element is connected to a spring with a spring path which is directed transversely to the heat absorption side and which holds the cooling member on the side of the brake disk. 